/*- * SPDX-License-Identifier: BSD-2-Clause * * Copyright (c) 2021 Alan Somers * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $FreeBSD$ */ extern "C" { #include #include #include #include #include #include #include #include "mntopts.h" // for build_iovec } #include "mockfs.hh" #include "utils.hh" using namespace testing; /* Is buf all zero? */ static bool is_zero(const char *buf, uint64_t size) { return buf[0] == 0 && !memcmp(buf, buf + 1, size - 1); } class Fallocate: public FuseTest { public: /* * expect VOP_DEALLOCATE to be implemented by vop_stddeallocate. */ void expect_vop_stddeallocate(uint64_t ino, uint64_t off, uint64_t length) { /* XXX read offset and size may depend on cache mode */ EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { return (in.header.opcode == FUSE_READ && in.header.nodeid == ino && in.body.read.offset <= off && in.body.read.offset + in.body.read.size >= off + length); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto in, auto& out) { assert(in.body.read.size <= sizeof(out.body.bytes)); out.header.len = sizeof(struct fuse_out_header) + in.body.read.size; memset(out.body.bytes, 'X', in.body.read.size); }))).RetiresOnSaturation(); EXPECT_CALL(*m_mock, process( ResultOf([=](auto in) { const char *buf = (const char*)in.body.bytes + sizeof(struct fuse_write_in); assert(length <= sizeof(in.body.bytes) - sizeof(struct fuse_write_in)); return (in.header.opcode == FUSE_WRITE && in.header.nodeid == ino && in.body.write.offset == off && in.body.write.size == length && is_zero(buf, length)); }, Eq(true)), _) ).WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, write); out.body.write.size = length; }))); } }; class Fspacectl: public Fallocate {}; class Fspacectl_7_18: public Fspacectl { public: virtual void SetUp() { m_kernel_minor_version = 18; Fspacectl::SetUp(); } }; class FspacectlCache: public Fspacectl, public WithParamInterface { public: bool m_direct_io; FspacectlCache(): m_direct_io(false) {}; virtual void SetUp() { int cache_mode = GetParam(); switch (cache_mode) { case Uncached: m_direct_io = true; break; case WritebackAsync: m_async = true; /* FALLTHROUGH */ case Writeback: m_init_flags |= FUSE_WRITEBACK_CACHE; /* FALLTHROUGH */ case Writethrough: break; default: FAIL() << "Unknown cache mode"; } FuseTest::SetUp(); if (IsSkipped()) return; } }; class PosixFallocate: public Fallocate { public: static sig_atomic_t s_sigxfsz; void SetUp() { s_sigxfsz = 0; FuseTest::SetUp(); } void TearDown() { struct sigaction sa; bzero(&sa, sizeof(sa)); sa.sa_handler = SIG_DFL; sigaction(SIGXFSZ, &sa, NULL); Fallocate::TearDown(); } }; sig_atomic_t PosixFallocate::s_sigxfsz = 0; void sigxfsz_handler(int __unused sig) { PosixFallocate::s_sigxfsz = 1; } class PosixFallocate_7_18: public PosixFallocate { public: virtual void SetUp() { m_kernel_minor_version = 18; PosixFallocate::SetUp(); } }; /* * If the server returns ENOSYS, it indicates that the server does not support * FUSE_FALLOCATE. This and future calls should fall back to vop_stddeallocate. */ TEST_F(Fspacectl, enosys) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; off_t fsize = 1 << 20; off_t off0 = 100; off_t len0 = 500; struct spacectl_range rqsr = { .r_offset = off0, .r_len = len0 }; uint64_t ino = 42; uint64_t off1 = fsize; uint64_t len1 = 1000; off_t off2 = fsize / 2; off_t len2 = 500; int fd; expect_lookup(RELPATH, ino, S_IFREG | 0644, fsize, 1); expect_open(ino, 0, 1); expect_fallocate(ino, off0, len0, FUSE_FALLOC_FL_KEEP_SIZE | FUSE_FALLOC_FL_PUNCH_HOLE, ENOSYS); expect_vop_stddeallocate(ino, off0, len0); expect_vop_stddeallocate(ino, off2, len2); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); EXPECT_EQ(0, fspacectl(fd, SPACECTL_DEALLOC, &rqsr, 0, NULL)); /* Subsequent calls shouldn't query the daemon either */ rqsr.r_offset = off2; rqsr.r_len = len2; EXPECT_EQ(0, fspacectl(fd, SPACECTL_DEALLOC, &rqsr, 0, NULL)); /* Neither should posix_fallocate query the daemon */ EXPECT_EQ(EINVAL, posix_fallocate(fd, off1, len1)); leak(fd); } /* * EOPNOTSUPP means "the file system does not support fallocate with the * supplied mode on this particular file". So we should fallback, but not * assume anything about whether the operation will fail on a different file or * with a different mode. */ TEST_F(Fspacectl, eopnotsupp) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; struct spacectl_range rqsr; uint64_t ino = 42; uint64_t fsize = 1 << 20; uint64_t off0 = 500; uint64_t len = 1000; uint64_t off1 = fsize / 2; int fd; expect_lookup(RELPATH, ino, S_IFREG | 0644, fsize, 1); expect_open(ino, 0, 1); expect_fallocate(ino, off0, len, FUSE_FALLOC_FL_KEEP_SIZE | FUSE_FALLOC_FL_PUNCH_HOLE, EOPNOTSUPP); expect_vop_stddeallocate(ino, off0, len); expect_fallocate(ino, off1, len, FUSE_FALLOC_FL_KEEP_SIZE | FUSE_FALLOC_FL_PUNCH_HOLE, EOPNOTSUPP); expect_vop_stddeallocate(ino, off1, len); expect_fallocate(ino, fsize, len, 0, 0); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); /* * Though the FUSE daemon will reject the call, the kernel should fall * back to a read-modify-write approach. */ rqsr.r_offset = off0; rqsr.r_len = len; EXPECT_EQ(0, fspacectl(fd, SPACECTL_DEALLOC, &rqsr, 0, NULL)); /* Subsequent calls should still query the daemon */ rqsr.r_offset = off1; rqsr.r_len = len; EXPECT_EQ(0, fspacectl(fd, SPACECTL_DEALLOC, &rqsr, 0, NULL)); /* But subsequent posix_fallocate calls _should_ query the daemon */ EXPECT_EQ(0, posix_fallocate(fd, fsize, len)); leak(fd); } TEST_F(Fspacectl, erofs) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; struct statfs statbuf; uint64_t fsize = 2000; struct spacectl_range rqsr = { .r_offset = 0, .r_len = 1 }; struct iovec *iov = NULL; int iovlen = 0; uint64_t ino = 42; int fd; int newflags; expect_lookup(RELPATH, ino, S_IFREG | 0644, fsize, 1); expect_open(ino, 0, 1); EXPECT_CALL(*m_mock, process( ResultOf([](auto in) { return (in.header.opcode == FUSE_STATFS); }, Eq(true)), _) ).WillRepeatedly(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { /* * All of the fields except f_flags are don't care, and f_flags * is set by the VFS */ SET_OUT_HEADER_LEN(out, statfs); }))); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); /* Remount read-only */ ASSERT_EQ(0, statfs("mountpoint", &statbuf)) << strerror(errno); newflags = statbuf.f_flags | MNT_UPDATE | MNT_RDONLY; build_iovec(&iov, &iovlen, "fstype", (void*)statbuf.f_fstypename, -1); build_iovec(&iov, &iovlen, "fspath", (void*)statbuf.f_mntonname, -1); build_iovec(&iov, &iovlen, "from", __DECONST(void *, "/dev/fuse"), -1); ASSERT_EQ(0, nmount(iov, iovlen, newflags)) << strerror(errno); EXPECT_EQ(-1, fspacectl(fd, SPACECTL_DEALLOC, &rqsr, 0, NULL)); EXPECT_EQ(EROFS, errno); leak(fd); } TEST_F(Fspacectl, ok) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; struct spacectl_range rqsr, rmsr; struct stat sb0, sb1; uint64_t ino = 42; uint64_t fsize = 2000; uint64_t offset = 500; uint64_t length = 1000; int fd; expect_lookup(RELPATH, ino, S_IFREG | 0644, fsize, 1); expect_open(ino, 0, 1); expect_fallocate(ino, offset, length, FUSE_FALLOC_FL_KEEP_SIZE | FUSE_FALLOC_FL_PUNCH_HOLE, 0); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(0, fstat(fd, &sb0)) << strerror(errno); rqsr.r_offset = offset; rqsr.r_len = length; EXPECT_EQ(0, fspacectl(fd, SPACECTL_DEALLOC, &rqsr, 0, &rmsr)); EXPECT_EQ(0, rmsr.r_len); EXPECT_EQ((off_t)(offset + length), rmsr.r_offset); /* * The file's attributes should not have been invalidated, so this fstat * will not requery the daemon. */ EXPECT_EQ(0, fstat(fd, &sb1)); EXPECT_EQ(fsize, (uint64_t)sb1.st_size); /* mtime and ctime should be updated */ EXPECT_EQ(sb0.st_atime, sb1.st_atime); EXPECT_NE(sb0.st_mtime, sb1.st_mtime); EXPECT_NE(sb0.st_ctime, sb1.st_ctime); leak(fd); } /* The returned rqsr.r_off should be clipped at EoF */ TEST_F(Fspacectl, past_eof) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; struct spacectl_range rqsr, rmsr; uint64_t ino = 42; uint64_t fsize = 1000; uint64_t offset = 1500; uint64_t length = 1000; int fd; expect_lookup(RELPATH, ino, S_IFREG | 0644, fsize, 1); expect_open(ino, 0, 1); expect_fallocate(ino, offset, length, FUSE_FALLOC_FL_KEEP_SIZE | FUSE_FALLOC_FL_PUNCH_HOLE, 0); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); rqsr.r_offset = offset; rqsr.r_len = length; EXPECT_EQ(0, fspacectl(fd, SPACECTL_DEALLOC, &rqsr, 0, &rmsr)); EXPECT_EQ(0, rmsr.r_len); EXPECT_EQ((off_t)fsize, rmsr.r_offset); leak(fd); } /* The returned rqsr.r_off should be clipped at EoF */ TEST_F(Fspacectl, spans_eof) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; struct spacectl_range rqsr, rmsr; uint64_t ino = 42; uint64_t fsize = 1000; uint64_t offset = 500; uint64_t length = 1000; int fd; expect_lookup(RELPATH, ino, S_IFREG | 0644, fsize, 1); expect_open(ino, 0, 1); expect_fallocate(ino, offset, length, FUSE_FALLOC_FL_KEEP_SIZE | FUSE_FALLOC_FL_PUNCH_HOLE, 0); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); rqsr.r_offset = offset; rqsr.r_len = length; EXPECT_EQ(0, fspacectl(fd, SPACECTL_DEALLOC, &rqsr, 0, &rmsr)); EXPECT_EQ(0, rmsr.r_len); EXPECT_EQ((off_t)fsize, rmsr.r_offset); leak(fd); } /* * With older servers, no FUSE_FALLOCATE should be attempted. The kernel * should fall back to vop_stddeallocate. */ TEST_F(Fspacectl_7_18, ok) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; struct spacectl_range rqsr, rmsr; void *buf; uint64_t ino = 42; uint64_t fsize = 2000; uint64_t offset = 500; uint64_t length = 1000; int fd; buf = malloc(length); expect_lookup(RELPATH, ino, S_IFREG | 0644, fsize, 1); expect_open(ino, 0, 1); expect_vop_stddeallocate(ino, offset, length); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); rqsr.r_offset = offset; rqsr.r_len = length; EXPECT_EQ(0, fspacectl(fd, SPACECTL_DEALLOC, &rqsr, 0, &rmsr)); EXPECT_EQ(0, rmsr.r_len); EXPECT_EQ((off_t)(offset + length), rmsr.r_offset); leak(fd); free(buf); } /* * A successful fspacectl should clear the zeroed data from the kernel cache. */ TEST_P(FspacectlCache, clears_cache) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; const char *CONTENTS = "abcdefghijklmnopqrstuvwxyz"; struct spacectl_range rqsr, rmsr; uint64_t ino = 42; ssize_t bufsize = strlen(CONTENTS); uint64_t fsize = bufsize; uint8_t buf[bufsize]; char zbuf[bufsize]; uint64_t offset = 0; uint64_t length = bufsize; int fd; bzero(zbuf, bufsize); expect_lookup(RELPATH, ino, S_IFREG | 0644, fsize, 1); expect_open(ino, 0, 1); /* NB: expectations are applied in LIFO order */ expect_read(ino, 0, fsize, fsize, zbuf); expect_read(ino, 0, fsize, fsize, CONTENTS); expect_fallocate(ino, offset, length, FUSE_FALLOC_FL_KEEP_SIZE | FUSE_FALLOC_FL_PUNCH_HOLE, 0); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); /* Populate the cache */ ASSERT_EQ(fsize, (uint64_t)pread(fd, buf, bufsize, 0)) << strerror(errno); ASSERT_EQ(0, memcmp(buf, CONTENTS, fsize)); /* Zero the file */ rqsr.r_offset = offset; rqsr.r_len = length; EXPECT_EQ(0, fspacectl(fd, SPACECTL_DEALLOC, &rqsr, 0, &rmsr)); EXPECT_EQ(0, rmsr.r_len); EXPECT_EQ((off_t)(offset + length), rmsr.r_offset); /* Read again. This should query the daemon */ ASSERT_EQ(fsize, (uint64_t)pread(fd, buf, bufsize, 0)) << strerror(errno); ASSERT_EQ(0, memcmp(buf, zbuf, fsize)); leak(fd); } INSTANTIATE_TEST_CASE_P(FspacectlCache, FspacectlCache, Values(Uncached, Writethrough, Writeback), ); /* * If the server returns ENOSYS, it indicates that the server does not support * FUSE_FALLOCATE. This and future calls should return EINVAL. */ TEST_F(PosixFallocate, enosys) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; uint64_t ino = 42; uint64_t off0 = 0; uint64_t len0 = 1000; off_t off1 = 100; off_t len1 = 200; uint64_t fsize = 500; struct spacectl_range rqsr = { .r_offset = off1, .r_len = len1 }; int fd; expect_lookup(RELPATH, ino, S_IFREG | 0644, fsize, 1); expect_open(ino, 0, 1); expect_fallocate(ino, off0, len0, 0, ENOSYS); expect_vop_stddeallocate(ino, off1, len1); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); EXPECT_EQ(EINVAL, posix_fallocate(fd, off0, len0)); /* Subsequent calls shouldn't query the daemon*/ EXPECT_EQ(EINVAL, posix_fallocate(fd, off0, len0)); /* Neither should VOP_DEALLOCATE query the daemon */ EXPECT_EQ(0, fspacectl(fd, SPACECTL_DEALLOC, &rqsr, 0, NULL)); leak(fd); } /* * EOPNOTSUPP means "the file system does not support fallocate with the * supplied mode on this particular file". So we should fallback, but not * assume anything about whether the operation will fail on a different file or * with a different mode. */ TEST_F(PosixFallocate, eopnotsupp) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; struct spacectl_range rqsr; uint64_t ino = 42; uint64_t fsize = 2000; uint64_t offset = 0; uint64_t length = 1000; int fd; expect_lookup(RELPATH, ino, S_IFREG | 0644, fsize, 1); expect_open(ino, 0, 1); expect_fallocate(ino, fsize, length, 0, EOPNOTSUPP); expect_fallocate(ino, offset, length, 0, EOPNOTSUPP); expect_fallocate(ino, offset, length, FUSE_FALLOC_FL_KEEP_SIZE | FUSE_FALLOC_FL_PUNCH_HOLE, 0); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); EXPECT_EQ(EINVAL, posix_fallocate(fd, fsize, length)); /* Subsequent calls should still query the daemon*/ EXPECT_EQ(EINVAL, posix_fallocate(fd, offset, length)); /* And subsequent VOP_DEALLOCATE calls should also query the daemon */ rqsr.r_len = length; rqsr.r_offset = offset; EXPECT_EQ(0, fspacectl(fd, SPACECTL_DEALLOC, &rqsr, 0, NULL)); leak(fd); } /* EIO is not a permanent error, and may be retried */ TEST_F(PosixFallocate, eio) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; uint64_t ino = 42; uint64_t offset = 0; uint64_t length = 1000; int fd; expect_lookup(RELPATH, ino, S_IFREG | 0644, 0, 1); expect_open(ino, 0, 1); expect_fallocate(ino, offset, length, 0, EIO); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); EXPECT_EQ(EIO, posix_fallocate(fd, offset, length)); expect_fallocate(ino, offset, length, 0, 0); EXPECT_EQ(0, posix_fallocate(fd, offset, length)); leak(fd); } TEST_F(PosixFallocate, erofs) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; struct statfs statbuf; struct iovec *iov = NULL; int iovlen = 0; uint64_t ino = 42; uint64_t offset = 0; uint64_t length = 1000; int fd; int newflags; expect_lookup(RELPATH, ino, S_IFREG | 0644, 0, 1); expect_open(ino, 0, 1); EXPECT_CALL(*m_mock, process( ResultOf([](auto in) { return (in.header.opcode == FUSE_STATFS); }, Eq(true)), _) ).WillRepeatedly(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { /* * All of the fields except f_flags are don't care, and f_flags * is set by the VFS */ SET_OUT_HEADER_LEN(out, statfs); }))); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); /* Remount read-only */ ASSERT_EQ(0, statfs("mountpoint", &statbuf)) << strerror(errno); newflags = statbuf.f_flags | MNT_UPDATE | MNT_RDONLY; build_iovec(&iov, &iovlen, "fstype", (void*)statbuf.f_fstypename, -1); build_iovec(&iov, &iovlen, "fspath", (void*)statbuf.f_mntonname, -1); build_iovec(&iov, &iovlen, "from", __DECONST(void *, "/dev/fuse"), -1); ASSERT_EQ(0, nmount(iov, iovlen, newflags)) << strerror(errno); EXPECT_EQ(EROFS, posix_fallocate(fd, offset, length)); leak(fd); } TEST_F(PosixFallocate, ok) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; struct stat sb0, sb1; uint64_t ino = 42; uint64_t offset = 0; uint64_t length = 1000; int fd; EXPECT_LOOKUP(FUSE_ROOT_ID, RELPATH) .WillOnce(Invoke(ReturnImmediate([=](auto in __unused, auto& out) { SET_OUT_HEADER_LEN(out, entry); out.body.entry.attr.mode = S_IFREG | 0644; out.body.entry.nodeid = ino; out.body.entry.entry_valid = UINT64_MAX; out.body.entry.attr_valid = UINT64_MAX; }))); expect_open(ino, 0, 1); expect_fallocate(ino, offset, length, 0, 0); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); ASSERT_EQ(0, fstat(fd, &sb0)) << strerror(errno); EXPECT_EQ(0, posix_fallocate(fd, offset, length)); /* * Despite the originally cached file size of zero, stat should now * return either the new size or requery the daemon. */ EXPECT_EQ(0, stat(FULLPATH, &sb1)); EXPECT_EQ(length, (uint64_t)sb1.st_size); /* mtime and ctime should be updated */ EXPECT_EQ(sb0.st_atime, sb1.st_atime); EXPECT_NE(sb0.st_mtime, sb1.st_mtime); EXPECT_NE(sb0.st_ctime, sb1.st_ctime); leak(fd); } /* fusefs should respect RLIMIT_FSIZE */ TEST_F(PosixFallocate, rlimit_fsize) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; struct rlimit rl; uint64_t ino = 42; uint64_t offset = 0; uint64_t length = 1'000'000; int fd; expect_lookup(RELPATH, ino, S_IFREG | 0644, 0, 1); expect_open(ino, 0, 1); rl.rlim_cur = length / 2; rl.rlim_max = 10 * length; ASSERT_EQ(0, setrlimit(RLIMIT_FSIZE, &rl)) << strerror(errno); ASSERT_NE(SIG_ERR, signal(SIGXFSZ, sigxfsz_handler)) << strerror(errno); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); EXPECT_EQ(EFBIG, posix_fallocate(fd, offset, length)); EXPECT_EQ(1, s_sigxfsz); leak(fd); } /* With older servers, no FUSE_FALLOCATE should be attempted */ TEST_F(PosixFallocate_7_18, einval) { const char FULLPATH[] = "mountpoint/some_file.txt"; const char RELPATH[] = "some_file.txt"; uint64_t ino = 42; uint64_t offset = 0; uint64_t length = 1000; int fd; expect_lookup(RELPATH, ino, S_IFREG | 0644, 0, 1); expect_open(ino, 0, 1); fd = open(FULLPATH, O_RDWR); ASSERT_LE(0, fd) << strerror(errno); EXPECT_EQ(EINVAL, posix_fallocate(fd, offset, length)); leak(fd); }